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English Pages 166 [188] Year 1989
Question of Biological Origins
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Of Pandas and People The Central Question of Biological Origins Second Edition Percival Davis
Dean H. Kenyon Charles
B.
Thaxton
Academic Editor
Haughton
Publishing Dallas, Texas
Company
Cover photograph: © Steve Kaufman/Peter Arnold, illustration: Debbie Smith
Inc.
Book
Copyright® 1989, 1993 by
Foundation
for
Thought and Ethics
Richardson, Texas. Fifth Printing No
2004
may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy recording or any information storage and retrieval system without permission wnting from the publisher.
All right reserved.
part of this publication
m
Pnmed
in the
United States of Amenca.
ISBN 0-914513-40-0
Acknowledgements of Pandas and People went through an
evolution
of its
own. The book's Project Chairman and Academic Edi-
many drafts. Over an extended period of time, the manuscript, either in part or m its entirety, was sent to scores of reviewers with very diverse perspectives. In addition, the book was used during its development for two years in a public school district in field test form, and feedback was taken into account in further revision. Although the manuscript was nearly always under review by someone, there was a general cadence to these reviews, which came in three basic rounds. First came a round by scientists engaged in teaching and research, then a round Charles
tor, Dr.
B.
Thaxton, supervised the review and revision process through
by high school teachers, then a second round by scientists. Many hundreds of valuable criticisms and suggestions were offered, from readers holding evolutionary views as well as others in general agreement with the authors. Upon publication of the hrst edition, additional valuable comments became available from a wider scientifically informed readership.
Our genuine thanks
to the following for their indispensable assistance
the manuscript; any errors of fact or interpretation are not theirs but our Critical
Robert
L.
Agnew
Donald F Calbrcath
of Natural and Social Sciences North Lake College Irvmg. Texas
Harold G Coffin Former Research Scientist Geoscience Research Institute
Robert M. Augros Professor of Philosophy
Loma Linda University Loma Linda, California
Anselm College Manchester, New Hampshire
Turner Collins
Donald M. Austin Former President of Anthropology
Evangel College
St.
Southern Methodist University
Texas
Richard A. Baer, Jr. Professor, Dept of Natural Resources Cornell University Ithaca,
New York
Arthur
L.
Battson,
Professor of Biology Springfield. Missouri
Thomas Thomas
Compton C. Emmel L.
University of Florida Gainesville, Florida
Norman III
L. Geisler
Dean
University of California
Charlotte, North Carolina
Santa Barbara, California L.
Baumgardner
Technical
Theoretical Division
Staff,
Los Alamos National Laboratory Los Alamos,
New Mexico
James Gibson
Lehigh University
San Francisco State University
Bethlehem, Pennsylvania
San Francisco. California Lois Harbaugh Science Teachcr,'''Chairperson
Probe Ministries, Intl. Richardson, Texas
Lake Highlands junior High Dallas, Texas
Walter
Arnold Hyndman Assoc Professor, Biological Sciences and Assoc. Provost
L.
Bradley
Head
Dept, of Mechanical Engineering
Texas
A&M
University
New
James O. Buswell,
T. Rick Irvin
III
Brunswick,
New Jersey
Assoc. Professor of Environmental Studies
The William Carey
Louisiana State University
University
Pasadena, California
Fred Sigworth Professor of Physiology
Gordon
Yale University
C. Mills
J.
Professor of Religion
Peter Vibert
Talbot School of Theology
Senior Scientist, Rosenstiel Center Brandeis University
Morrill
High School Science Instructor
Waltham, Massachusetts
Donald Munro
John
ol Biolog)'
L. Weister Chairman, Committee
chair
Education
American
Paul A Nelson Ph D candidate University of Chicago Chicago, Illinois
S.
Baton Rouge, Louisiana
R.
Pearcey
(Overview Chapter)
Rod Clark
A. James Melnick Joseph E. O'Day Audris Zidermanis 111
Scientific
Affiliation
Buellton, California
Harold
Dean
T
Wiebe
of Graduate School
Professor of Biology Seatde Pacific University
D. Palmer
Seattle,
Alvin Plantinga
Washington
John A O Brien Dept Chair and Professor of Philosophy
David L. Wilcox Chairman. Biology Department
University of Notre Dame Notre Dame, Indiana
St
David Price Former Professor of Science Education
Asst, Professor ot Science
University of California at Los Angeles Los Angeles, California
Bryan College Dayton, Tennessee
Eastern College Davids, Pennsylvania
Kurt Wise
Editors and Contributors
Nancy
for
Integrity in Science
J.
Vice President for Academic Affairs Intl
Whitworth College Spokane, Washington
Professor of Biology
Kenneth O'Loane Research Chemist
Rutgers University
College Station, Texas
Oxford University Oxford. England
Houghton College Houghton, New York
Astronomy
Director ot Research
Professor and
Stephen C. Meyer Asst Professor of Philosophy
Dept
Charles Hagar
G. Bohlin
David M. Shotton
Tim Institute
Loma Linda University Loma Linda. California
Michael J. Behe Assoc Professor of Chemistry
Raymond
New Jersey
Alexander Mebane Research Organic Chemist
La Mirada, California
Research Scientist Geoscience Research
Professor of
Superintendent Chattanooga Public Schools Chattanooga, Tennessee
Princeton University
New Haven, Connecticut Emeritus Professor of Biochemistry, Dept. of Human Biological Chemistry and Lee Spencer Genetics Paleontologist Bureau of Land University of Texas Medical Branch Galveston, Texas Management Salt Lake City, Utah P. Moreland
Professor of Zoology
Southern Evangelical Seminary
R.
all oi
Harry J. Reynolds
Robert Kaita Principal Research Physicist Plasma Physics Laboratory Princeton,
Director of Instructional Resources
John
review of portions or
own:
Reviewers
Dean
Dallas,
m the
Gordon
E.
Peterson
David N. Quine
Contents User's Guide to the
Book
v
Introduction
Of Pandas and
vii
People:
An
Overview
1
Excursion Chapter One: The Origin of Life Excursion Chapter Two: Genetics and Macroevolution
41 .
.
59
Excursion Chapter Three: The Origin of Species
77
Excursion Chapter Four: The Fossil Record
91
Excursion Chapter Five: Homology
115
Excursion Chapter
135
Six:
Biochemical Similarities
Glossary
149
A Note to Teachers
153
Index
165
Authors and Contributors
169
Credits
170
IV
Guide
User's
Book
to the
The authors and editors of this book have provided and easy to use as possible.
several special features to
make
it
as
flexible
Subjects
on Two
Levels
They have written the book, ments of the subjects are found
for
example, on two
in the first chapter,
levels. Lighter,
easy to understand treat-
"Of Pandas and People: An Overview."
More in-depth treatments of the same material are provided in the Excursion chapters that follow. The authors have included the in-depth material because it is easy to sacrifice accuracy when trying to make a scientific subject easy to follow, and this is a subject where accuracy is important. If you plan to read one or more of the Excursion chapters, be sure to read the matching Overview section or sections first. (Section 1 of the Overview is elaborated on in Excursion Chapter 1, Section 2 in Excursion Chapter 2, etc.) You will find the more challenging Excursion chapters especially helpful if you plan to do a special project or paper on some subject area covered by the book.
Vocabulary Glossary Even
if
you
will notice that
find the Excursion chapters challenging, there are several helps provided.
some words
are in boldface.
Any boldfaced word
is
You
defined for you in the Glos-
same word might be used several times, but it is only in boldused in the Overview chapter and the first time it is used in the Excursion chapters. If you have any doubts about the meaning of a word in boldface as you are reading, check it out then.
sary at the end of the book. This face the first time
it is
Pronunciation Bi^sssfe* .'.xv^'ssm^mscsi
Before you have read very for a technical
word
that
is
far,
you
will
come upon
a
pronunciation guide
not easily pronounced unless you have heard
it
in
parentheses
before.
These
pronunciation guides are easy to follow, and will help you use the terms in discussion as well as to "hear" them correctly, even when reading silently.
Emphasis You
will also see certain
words
in italics. This
may be
emphasize a term, either technical or general, in order Technical terms in
where
italics
italics
are
is
for
tor either of two reasons: 1) To you get at the heart of the subject.
are usually explained or defined right in the discussion. In cases
are used for emphasis, the
Over\'iew chapter, and once again, of italics
to help
at
word
is
only italicized in
its first
most, in the Excursion chapters. 2)
genus and species names of organisms. In these cases,
it
is
appearance in the
A
second purpose used each time they
named.
Easy Access to Subjects Index
An
index
is
provided in the back, so that if you want to find out what the book says about whether you have already read about it in the book or not, you can find the
a specific subject,
pages
to turn to for that subject.
Reference to Main Textbook Occasionally the authors will refer you to your main textbook concerning a subject.
unsure about that subject or concept, it might be worthwhile index of your main text and review it briefly. feel
Lists of
for
you
to
look
it
up
If
you
in the
References
Since the Excursion chapters surpass the Overview chapter in depth of treatment, refer-
ences to scientific literature are listed
at the
end of each Excursion chapter and of A Note
Teachers.
VI
to
IntroducQon We
age. These are times of stunning changes in economic well-being, moral and ethical precepts, philosophical and religious perspectives, and human self-knowledge, as well as in our understanding of that vast universe in which we are embedded like a grain of sand in a cosmic ocean. As long as there have been human beings, we have posed the deep and fundamental questions, which evoke wonder and stir us into at least a tentative and trembling awareness, questions on the origins of consciousness; life on our planet; the beginnings of the Earth; the formation of the Sun; the possibility of intelligent beings somewhere up there in the depths of the sky; as well as, the grandest inquiry of all— on the advent, nature and ultimate destiny of the universe.' — Dr Carl Sagan live in
an extraordinary
social organization,
Carl Sagan, one of the foremost popularizers of
science
i
ancient,
i
n our
time, has
drawn our
forms through the centuries, there is, nevertheless, a modern proponents of each
central core idea that
attention to
mportant, and fascinating questions.
How
view hold
come into existence? How harbor life? What docs it all
did thisii nmense universe did the e arth
come
to
all
if
selves
fit
Two
common
with their forebears. Through
the ages some have held the concept of life emerg-
ing from simple substance.
and how do mere mortals like ourscheme of things, if indeed there be a scheme? As Dr Sagan reminds us, we are not the fi rst to wonder, nor are we likely to be the last, mean,
in
into the overall
the substance
is,
took,
and the mechanism of
emergence, chance or
law,
are details that have
changed
many
what form
a nything,
What
the
first life
to characterize
different theories of
natural origin. Likewise, proponents of intelligent
design throughout history have shared the concept
different concepts of the origins of living
things heive long histories extending from ancient
that
times to the present. While both have taken varied
intelligent Vll
life,
manufactured object, is the result of shaping of matter Within intelligent
like a
design
how
also, the details as to
and over what span of time, Despite
all
Evidences of creatures that once lived but are no One has only to visit areas
gradual or abrupt,
longer with us abound.
differ
such as Dinosaur National Monument, or other fossil beds to be staggered by the variety and enormous size
society has learned, answers given for
remain in conflict or uncertain. Uncertainty keeps science— a quest for knowledge —alive. We should be thankful for those who have been brave enough to persist in asking important questions, for they have breathed Ufe into our the big questions
of these extinct forms, creatures that
tific
bony to
present data from
We
of biological origins.
answers, nor
to unveil
The Truth.
Our purpose,
view
is
From
bones differ considerably between organand the limbs themselves have different functions. What can such patterns mean, and how are they to be explained? Most agree without hesitation that there are patterns. The problem arises when it comes to interpretations of cause: mere probability,
rather,
better,
"family resemblance," or the product of intelligent
these six areas of science,
we
design?
will present
proposed by those today
The
hold the two alternative concepts; those with a Darwinian frame of reference, as well as those who adhere to intelligent design. We will concentrate, however, on explaining what few other textbooks do: the scientific rationale of the second concept. Our intention has been to give you presentations that will balance the biology curriculum. For what might be a refreshing change, you are asked to form your own opinions. If you understand the information presented, you are fully capable of drawing your own
explore
arise.
the
produced only by
random
into being in the first place, and complex structures of organisms Have you ever wondered how we can explain eye,
The
or the marvel of
flight in
stood. Science includes
many
elements;
includes
it
world around us we observe two classes of and mountains, and man-made creations, such as houses and computers. In the
are
things: natural objects, like stars
numknown m such abundant supply
earth's surface to collect in great
fossils are
these speak of
asking what causes things.
birds?
of once-livmg organisms
fossils
Do
be honest: we do not have all the answers, and we will not in the near future, despite what some would have you believe. Science can provide us with additional answers, however, if used patiently, and if under-
came
found near the bers.
living things.
natural causes, or of something intelligent?
the elegantly
Enough
intriguing differ-
We live in an exciting time We have the technology that makes possible more observations than were available to any who lived before us. Coupled with these, we have intelligence enough to propose sophisticated explanations for what we see. But let us
will
human
m living things, reveal
and equally
ences. Evidence to date forces us to conclude they are
first
species
to
flesh
intriguing similarities
be given an opportunity to examine data with how life may have arisen. Once that has been addressed, you can delve into what science has to say about the impact of genetics and environment on shaping groups of organisms that we commonly refer to as species. This raises the questions of
how how
century has permitted science
staggering array of roles to play
conclusions.
You
last half
more than
and bone, fascinating as they are. It is now possible to compare and contrast organisms, be they plant, animal, or other, by their body chemistry. Proteins, a vast army of molecules with a
who
dealing
vertebrates, animals with
see repeating patterns in fore-
isms,
the only reasonable one.
interpretations of the data
we
the various
and to see why the data may be viewed in more than one way. There will be no attempt to kid you— to tell you that a complex issue is simple, or that the authors' help readers understand origins
to
examine the
skeletons,
limbs and hindlimbs, even though the proportions of
on the central question don t propose to give final
six areas of science that bear
is
productions of television and movies.
When we
existence.
This book has a single goal:
no longer roam
the face of our planet, except in the woefully unscien-
this into the context of origins, of
how
things
that a century ago, the
Smithsonian Institution gave specimens of marine just one year Today, many milinvertebrate fossils lions are available for examination. Do they have a
To put
away almost 25,000
arose,
story to
whether something resulted from natural or from
"leftover"
m
we
see things resulting from two
tally different If
tell?
Vlll
we
causes: natural
didn't see
it
and
occur,
fundamen-
intelligent.
how do we
decide
We
intelligent causes?
thought.
We
do it without giving it much and we have decided that
included in science classrooms.- Other surveys of science
see clouds
they are the result of natural forces.
shapes
intricate their
may
be,
No
how
matter
we understand
that
greater levels of interest
all
clouds are simply water vapor affected by wind and
Walking along a beach you may be impressed by
may be
artistic
but
it
isn't likely that
The scene
you would look
artist who might be responsible. A you rightly conclude. But if you come across words unmistakably reading "John loves Mary" etched into the sand, you would know that no wave action was responsible for that. Nor would you be likely to imagine that, given enough time, grains of sand would spontaneously organize themselves so uniquely. Rather, you would look around for an intelligent cause: John perhaps even Mary. What do these examples suggest? The way we decide whether a given phenomenon arises from natural or intelligent causes is from experience, refined as we mature and are exposed to more and more examples. Through this process, our experience grows into a collection of uniform obser-
around
an
for
natural cause,
.
.
vides a lighter treatment of a broader range of topics.
Wander back and to
all
.
example,
cause This
what must happen,
is
scientists are to recognize
if
cause.
interesting, honest,
We
and not
Recently the US. that
hope
its
You may read introduction to the
challenging discussion of the subjects in the six
of learning,
want to
Ohio
roughly one
fifth
creation in their
at
1.
3.
all
of
"An Overview" and each of the
six
help you go even deeper People
if
is
itself.
you want
to.
not intended
We have given
to
be
a
a favora-
and raised reasonable doubt about natural descent. But used together with your other text, it should help to balance the overall curriculum. By now you are aware that you have a mind of your own. Here is a good opportunity to use it. We hope that you will enjoy dealing with ideas and coming to conclusions on your own. Of course, you may modify your understandings as you learn more in the years to come. Meanwhile, we expect that Of Pandas and People could become an exciting event in your educational journey. ble case for intelligent design
sig-
about the same time showed that
were already presenting the idea of science classes, and a quarter of the
teachers surveyed believed that the subject should be
2.
read
balanced treatment by
since a survey of high school biology
teachers in
to
0/ Pandas and
clear
is
"go for it"— to dig deeper
to
Excursion chapters. These chapters have references
for
overstated.
evolutionary views in their classrooms. This
and you want
so you will understand more. In that case you will
teachers have the right to present non-
nificant,
follow.
Perhaps you have already discovered the rewards
presentations are
it
this chapter on its own, or as an more detailed, more academically
Excursion chapters that
evidences of
Supreme Court made
of
covered, should time or interest be limited.
Sagan speculated they might. 0/ Pandas and People presents evidences, found in the data of biology, for intelligent
first
"Of Pandas and People: An Overview," treats the major topics of the book. It gives you the
option of gathering only the essence of the six areas
beings elsewhere in the universe, as Carl
intelligent
between the two, using each
This publication has a special design. The
we learn to count on. If experience has shown that a certain class of phenomena results from intelligent causes and then we encounter something new but similar, we conclude its origin also to be from intelligent
forth
enrich the other
chapter,
vations, things
an
among teachers.
The authors and publisher want you to use this book as a supplement, not a substitute, for your biology text; it cannot replace the main textbook. But without Of Pandas and People, you would miss a lot of interesting science. We hope you finish this book respecting good scientists of all persuasions; we do. The subjects here are treated in depth, and digging deeper brings richer rewards. Your textbook pro-
temperature.
the regular pattern of ripples in the sand.
including a nationwide market
teachers,
study done for this book,^ confirm the same or
New York: Random House, from the Introduction. Michael Zimmerman, 1987. "The Evolution-Creation Controversy: Opinions of Ohio High School Biology Teachers," Ohio
Carl Sagan, 1974. Broca's Brain.
Journal of Science, 1987 4: pp. 115-125. Available from Foundationjor Thought and Ethics,
P.O.
Box 830721, Richardson, Texas 75083-0721. IX
Of Pandas and
OVERVIEW SECTION
People:
An
Overview
1
The Origin of Life There was a time
when people
believed
some
animals arose on their own, full-blown, from non-
The
was
"spontaneous seem to be no more than superstition, but at one time it seemed to be confirmed by common-sense experience. Leave rotting meat out, and isn't it quickly covered with maggots? Leave dirty rags in the corner of a shed, and doesn't it soon become a nest of mice? With the rise of scientific method, however, belief living matter
belief
called
generation." Today the idea might
spontaneous generation began to be discredited. In 1668 Francesco Redi conducted an experiment to determine whether worms arose spontaneously in decaying food. He placed similar samples of raw meat m two sets of jars. One set he covered with a muslin screen, the other he left open. After several days, the muslin screen covering the first sample was sprinkled with fly eggs, but there were none on the meat itself The meat in the open jar was covered with eggs, which soon hatched into maggots, Redi had shown that maggots were not simply small worms in
that arose spontaneously, but rather
He had demonstrated scientifically life can come only from life.
were
fly
larvae
that at least
some
As the idea of spontaneous generation began to its last outpost was the world of microscopic life. The microscope had revealed the existence oi a world hitherto invisible and unsuspected. Microscopic creatures were so small, and appeared to be so simple, that it was not difficult to believe they arose spontaneously from nonliving matter After all, if bits of straw were left to rot in a pan oi water, the water was soon swarming with bacteria. wane,
In the early 1860s, Louis Pasteur laid this notion to rest as well.
He showed
that water coukl
be kept
by boiling it and then exposing it to only purified air By doing so, he proved that the microscopic life that mysteriously appeared as the straw rotted was the result of airborne bacteria. At the same time Pasteur was doing his research, Charles Darwin and others were formulating the free of bacteria
mechanistic theory of evolution. Pasteur's discoveries
(because
it
assumes
began
life
in a sea of
chemicals called the prebiotic soup). The
Oparin hypothesis has become the standard evolutionary approach to the origin of life Oparin and subsequent scientists suggested that chance interactions of chemicals and compounds would not eventually lead to viable molecules. Louis Pasteur,
who
Scientists
no longer
feel that
chance
is
proved that the ideas of spontaneous
enough. Instead, they theorize that some
generation of his time -were not valid.
the ordered structure
internal tendency of matter gives rise to
we
compounds. According matter has within
see in living
to today's view,
itself a
tendency
toward self-organization leading
Life in a Test
One
to
life.
Tube
of the advantages of Oparin's hy-
some extent, it could be tested. Not directly tested, of course, because we cannot subject a past event pothesis was that, to
were
all
very well for the advance of
scientific
knowledge, but they were
somewhat disturbing
for the notion of a
purely natural origin. Redi and Pasteur
had shown that full-blown organisms do not arise from nonliving materials, whether mice or microbes. Yet Darwinism, the dominant theory of evolution, seemed to require some type of natural origin. How was this possible? Then, in the 1920s, a Russian scienA.I. Oparin suggested a new approach to the question. Life did originate from nonliving matter he proposed, but not all at once. Instead, it arose very gradually in a series of stages. As biochemists have studied the chemistry of life, details of these stages have since also been suggested: simple chemicals combined to form organic compounds, such tist
like
the origin of
life
to
observation.
Instead, scientists can construct stories
about the events that may have happened, and then set up laboratory experiments to see if similar events will occur today.
These are
called simulation experi-
ments, because they are designed to
happened on
simulate what might have the early earth
when
life
Oparin suggested
named
chemical reactions in
began.
that
life
among
the atmosphere:
arose from
simple gases
methane, ethane,
ammonia, hydrogen, and water vapor These reactions were activated by various forms of energy in the environment— by lightning, heat from volcanos, kinetic energy from earthquakes, or light from the sun. When they encountered this
were con-
as
energy, the atmospheric gases
to
verted into
Oparin's hypothesis is referred to as prebiotic evolution (prebiotic means "before life") or chemical evolution
pounds to form amino acids, fatty acids, and sugars. These accumulated in the primitive oceans until there were enough to link up and form even larger, more complex molecules, such as proteins and
amino acids, which in turn, combined form large, complex molecules, such as proteins, which aggregated to form an interconnecting network and a cell wall.
more complicated com-
DNA.
Eventually these molecules
bined
to
com-
community
as the results of these experi-
coacervates (co-AS-er-vates, liquid
ments were first published. The success of such early experiments greatly
drops or bubble-like structures). From
increased the credibility of evolutionary
form integrated particles called
complete with cell membrane, complex metabolism, genetic coding, and the abilthese there arose the
ity to
first
true
cell,
reproduce.
How has
this
hypothesis been tested have taken
in the laboratory? Scientists
the simple gases suggested by Oparin,
mixed them together and subjected them to various energy sources, such as ultraviolet light (to simulate sunlight) and electrical
discharges (to simulate light-
and Harold such experiment. substance formed in the
ning). In 1953, Stanley Miller
Urey reported the
A gooey,
tar-like
first
Examining it. Miller identified several of the amino acids found in proflask.
teins today. Since then, other biological
compounds have been detected
in similar
atmospheric simulation experiments.
The tial
list
now
includes most of the essen-
kinds of organic
compounds found
theory. But
that
scientists
sought
occur
readily.
to
go
But the chemical reac-
tions required to
form proteins and
do not occur
readily.
In fact,
DNA these
products haven't appeared in any simulation experiment to date. In addition, some scientists have
been very
in
tions living things.
when
beyond the simplest building blocks of life, the momentum slowed. The step from simple compounds to the complex molecules of life, such as protein and DNA, has proved to be a difficult one. Thus far, it has resisted all efforts by the scientists working on the problem. The problem is that some chemical reactions occur quite readily, whereas others do not. The simple building blocks of life form relatively easily. They form in reactions belonging to the classes
critical
made
of some of the assump-
in constructing simulation
experiments. The procedures of such
experiments should, after all, simulate what might reasonably have happened under natural conditions. Yet many doht. Stauley Miller,
Oxygen
in the Air
Eor example,
all
.shown here with the
experiments simulating
the atmosphere of the early earth have
eliminated molecular oxygen.
The reason
oxygen acts as a poison preventing the chemical reactions that produce organic compounds. Furthermore, if any chemical compounds did form, they would be quickly destroyed by oxygen is
that
reacting with them, a process called oxi-
(Many food preservatives are simply substances that protect food from dation.
the effects of oxidation.)
For these reasons, the standard story
Unnatural Conditions Imagine the excitement
in the scientific
assumes that there was no oxygen present in the earths atmosphere at the origin of life. Yet scienof chemical evolution
apparatus used in his onginal origin of life experiments as a young graduate student.
-
Protein
and DNA The pro-
molecules. tein
molecule (A)
is
shown in its folded up form, which is secured hy chemical and physical forces
between
and
its
parts,
therefore differ
ait for each
individual protein.
The DNA (B) is shown in its famous double helix (corkscrew) form.
tists now have strong evidence that oxygen was present on the earth from the earliest ages. Many minerals react with oxygen (like the rusting of iron), and the resulting oxides are found in rocks dated earlier than the development of life according to the hypothesis. Moreover, significant levels of oxygen would have been necessary to produce ozone which would shield the earth from levels of
energy (heat, for example, or
early earth's
atmosphere would have
to
include oxygen.
Reversible Reactions
A
second barrier faced by any theory of chemical evolution can be stated as a paradox. Some chemicals react quite readily with one another They connect easily, like the north and south poles of two magnets. Others resist reacting. Getting them to react is like forcing the magnets' north ends together To drive such a chemical reaction forward requires
the
others will
break down. Since the process of destruction
a realistic simulation of the
is
compounds may form but
ultraviolet radiation lethal to biological life Clearly,
electricity).
paradox— energy also breaks chemical compounds apart. In fact, energy is actually more likely to break them apart than to cause them to bond in the first place. When a chemist exposes a mix of chemicals to heat or electricity, some
But— and here
is
actually
more
likely to occur,
amount compounds. Those that do of chemical simple ones, since will generally be form any complex molecules that might form would quickly break back down to their the net result will be only a small
simpler components.
amino and other products that form are siphoned off through a trap in order to protect them from breaking back down again. But there is no evidence of anyIn simulation experiments,
acids
thing in nature that acts as a counterpart to such a trap. Results reported from experiments with traps are therefore
overblown. The procedures of such
When amino
experiments should, alter
laboratory, the result
duplicate
all,
what might reasonably have happened under natural conditions. Yet many don't. Those that don t undermine the whole purpose of trymg to simulate nature.
acids are synthesized in the is
an equal mixture
and lefthanded gloves. In this and other ways, life shows characteristics that appear to be alien to anything produced under natural ol
both forms,
like a pile of right-
conditions.
Chemistry in 3-D
Cross-Reactions
Amino acids, sugar, protein, and DNA are
The fact that some reactions occur readily whereas others do not creates another problem. As we have said, the reactions
not simply strings of chemicals. For one thing they exhibit very specific three-
When
dimensional structures.
synthe-
may have
sized in the laboratory, they
chemical constituents but
right
still
involved in the formation of biologically
important
ex-
have
wrong three-dimensional form. For example, amino acids appear in
hibit the
tions.
two forms that are mirror images of each
is
other (see Figure 1) just as a right glove the mirror image of a
forms are referred
handed amino
left
glove.
to as right-
compounds are the kind that made under artificial condiAmino acids, for example, do not
the
is
The two and left-
acids. Living things use
only left-handed amino acids in their
MIRROR
to
be
readily react with each other
do
that they
Herein
substances.
A
corollary
react readily with other lies
a
problem.
If
amino acids formed on the early earth, they would not float around in lakes and ponds simply waiting for the right partner amino acids to show up in order to form proteins. Instead, they would combine with other
compounds in all sorts of up and unavailable
cross-reactions, tied
/
H,N
for
NH,
any biologically useful function (see
Figure
HOOC
COOH
C
/
D-AA
To summarize, most simulation experiments do not actually mimic in a realistic way the conditions that would have existed on the early earth. Taking into account the presence of oxygen, the
proteins.
Right-handed ones don't
the metabolism of the cell any
right-handed glove would
hand.
If
finds
its
just
fit
"fit"
more than a
onto your
left
one right-handed amino acid
way
is
large yields of non-biological goo.
CH,
L-AA
This explains why, in actual
experiments, the predominant outcome
—
HX
2).
into a protein, the protein's
reversible
reactions,
cross-reactions,
fact of
the prevalence of
and the lack of uniform we must conditions on the early
three-dimensional structures,
conclude that earth
were
far
from favorable
for the
spon-
reduced, often com-
taneous emergence of living things. The
happened, only right-hand-
Researchers have found no natural
most probable scenario of early earth history is not one of synthesis but of destruction. The experiments do not support the
conditions they can incorporate in simu-
idea that there exists an inherent tendency
ability to function is
pletely (As
it
ed sugars are used in
lation
DNA and RNA.)
experiments that
will
produce only
the correct three-dimensional stmcture.
toward self-organization within the ing materials.
start-
1. Amino come in (wo
Figure acids
fonns "righthanded (D-) and '
'
left-handed" (L-).
Both forms of the amino acids alanine are shown here.
most
The Language of life
scientists define
life
with reference
coded information in the DNA. It is this information that governs the development and functioning of all the cells in our bodies.
to the
We
from newsand even some textbooks
often get the impression
paper
articles
that scientists have
come
close to "creat-
ing life" in the laboratory. Yet
compounds
synthesized in the laboratory
fail
to
exhibit the special sequences or the
three-dimensional structure necessary for biological functioning.
Though life is made of simple chemiwe should not conclude that living
cals,
things are themselves simple. Shakespeare's sonnets are artistically complex,
though they are composed of simple letters made to form words and phrases. Mozart's pieces are musically complex, though they consist of simple notes placed in patterns. The decisive factor in living things
is
not the simple compo-
nents but the patterns.
What
life?
DNA molecule,
origin of
life,
knows
it.
In the
classes rivers
world around
of things:
2.
acids from reacting
with innumerable
other ingrediaits of the primordial soup, thus tying them up
and ending
their
potaUial
become
to
useful protein
molecules.
us,
we
see two
natural objects, like
and mountains, and man-made houses and computers. To
structures, like it
in the context of origins,
we
see
things resulting from two kinds of causes: natural
and
amino Cross reactions. In a primordial soup, nothing would prevail chains of amino Figure
then, includes the
coded information. The large molecules crucial to life, such as protein and DNA, are constructed much like a message in a known language, with chemicals acting as letters and combining in defined sequences to form words, phrases, and sentences. The "message" is decoded by the cell much the same way the dots and dashes of messages in Morse Code can be decoded by anyone who
put
patterns are essential to
Since the discovery of the
The
origin of
intelligent.
acids
7
Uniform Experience
tions.
The
results
consistently
How do we decide whether something is the result of natural processes or intelligent causes? Most of us do it without even thinking. We see clouds and we know, based on our experience, they are
No matter may be, we
the result of natural causes.
how intricate the shapes know that a cloud is simply
water vapor shaped by the wind and the temperature. On the other hand, we may see something looking very spells out the
much like a cloud
words "Vote
We know
that,
white and
fluffy like
for
words
cannot be the result of natural causes.
to
occur
we formulate other words, when scientists probed the nucleus of the cell, they eventually stumbled upon a phenomenon In
akin to finding "John loves Mary" written
Smedley" written sky The greatest difference is that the DNA text is much more complex. If in the sand, or "Vote for in the
the
amount
one
cell
of information contained in
of your it
that
even though they are
we observe
regularly are the basis of
the laws
a typewriter,
Smedley
clouds, the
and
body were written out on would fill as many books
as are contained in a large library
Are natural causes capable of producing these kinds of patterns? To say that
DNA
and protein arose by natural
causes, as chemical evolution does,
is
to
say complex, coded messages arose by natural causes.
It is
akin to saying "John
Mary" arose from the action of the waves, or from the interaction of the loves
grains of sand.
It is
like
saying the paint-
ing of a sunset arose spontaneously from
Even the
atoms in the paint and canvas. When in our experience have we ever witnessed such an event? Whenever we recognize a sequence as meaningful symbols we assume it is the handiwork of some intelligent cause We make that assumption even if we cannot decipher the symbols, as when an archaeologist discovers some ancient inscription on stone If science is based upon experience, then science tells us the message encoded in DNA must have originated from an intelligent cause. What kind of intelligent agent was it? On its own, science cannot answer this question; it must leave it to religion and philosophy But that should not prevent science from acknowledging evidences for an intelligent cause origin wherever
message, ifmeaniugful, speaks uumis-
the
Why
not? Because our experience— and
everybody else— tells us that do not give rise to complex structures such as a linguistic message. When we find "John loves Mary" written in the sand, we assume it resulted from an intelligent cause. Experience is that of
natural causes
the basis for science as well.
fmd
a
When we
complex message coded
nucleus of a
cell, it is
into the
reasonable to draw
same conclusion. Science uses conexperiments to determine what sort of results occur under given condithe
trolled
they
than
may exist. This is no different, really if we discovered life did result from
We still would not know, trom science, if the natural cause was all that was involved, or if the ultimate explanation was beyond nature, and using the natural cause natural causes.
briefest
takahly of an intelligent source.
Genetics and Macroevolution OVERVIEW SECTION
Behold the
oversized hmbs,
giraffe:
2
longer neck to survive, Darwin put an
stretched-out neck, ungainly posture—
environment favoring organisms with
everything apparently precariously out
longer necks, and then preserving any
of proportion.
And
yet
its
parts are
mar-
velously coordinated with each other;
moves with
graceful ease
and
such a powerful kick that
it
has been a puzzle
it
was important
Darwin's
rise to
new
traits.
To
perish depending on whether they are
one of Darwins its
giraffe's
constant
reach leaves to
to
to
to evolutionists
long neck resulted from
upward
Clearly,
maintain that organisms either survive or
predecessors, suggested that the
stretching
it
of the
since before the time of Darwin. Jean Baptiste de Lamarck,
as
theory to locate the "something" within
organisms that gives
The outlandish body shape
giraffe,
turned out.
delivers
has few
it
natural enemies.
giraffe
happened along— the
that
eat.
well suited to the environment
new
insight.
was no
What was unique
about
Darwin's theory was his idea that some force within organisms could
new
traits that
produce
over time would accumu-
Bone structure changed in response to the animals need to reach ever higher But scientists now know that body structure does not respond to an organisms needs or habits. If it did, Olympic racers should give birth to yet faster racers, and
late to
the children of intellectuals should be
Gregor Mendel was conducting experiments to answer just that question. Men-
even smarter than their parents. Darwin's theory of natural selection turned Lamarck's explanation around: instead of the environment giving rise to habits,
which
in turn
produce new
Darwin maintained within the organism
new
that itself
traits,
something gives rise to
which are then either preserved or weeded out by the environtraits,
ment. In place of an organism needing a
produce an
entirely novel sort of
organism.
What
force could this be?
Darwin
himself did not know. But ironically, the his
at
same time Darwin was constructing theory,
an Austrian
monk named
del discovered that traits could be lost in one generation only to reappear in a later generation. For example, when he crossed a pea plant bearing wrinkled seeds with one bearing round seeds, all the offspring in the first generation had round seeds. Was the wrinkled trait lost? Not at all; it reappeared in the next generation of pea plants.
Mendel concluded governed by particles passed from parent
that heredity
is
genes)
(later called
A
to offspring.
trait
might disappear temporarily, but the gene that codes for the trait remains
may
present within the organism and
be passed on
to its offspring.
breeder, for example, causes
When
some
appear or disappear,
acteristic to
a
char-
this re-
presents neither a true gain nor a true loss.
It
represents merely the interplay oi
ism is referred to as neo-Darwinism). Mendelian genetics held promise for Darwinism. For instance, it explained why a single new advantageous trait could survive and eventually become dominant in a population. Yet Mendelian genetics has proved to be a mixed blessing for Darwinian theory On the one hand, it provides the stanecessary for a
bility
dominant and recessive genes. A "lost' trait may still be present and may reappear A "new" trait that seems to appear out of nowhere may not be new at all but
hand,
simply the expression of a recessive gene
How
that existed
all
along.
When breeders pro-
duce new show dogs or meatier catde, they have actually shuffled genes around to
bring
some
ranging as to
web
change is to be so farproduce the whole complex if
of life from a single-celled organism.
does change occur within the framework of Mendelian genetics? This is the question we will answer in the next chapter
of these recessive genes to
Does Nature
expression.
The irony
become the other
what Darwinism
stability is just
doesn't need
to
On
trait
established in a population.
is
that
Select?
Darwin was de-
ing that living things are remarkably sta-
Darwin bred animals and was impressed by what could be accomplished through breeding. And with good reason; by
Perhaps partly because of Darwins
selecting animals with particular traits
veloping a theory of constant change the
at
same time Mendel was demonstrat-
ble.
success in focusing attention on change,
and allowing them
to
Mendel's theory was not taken seriously
breeders are often able
to create greater
until the first
Up
decade of the twentieth cen-
most commonly held concept of inheritance was a tury.
to
"paint-pot"
this point, the
model— the
father's contri-
reproduce,
differences within a single species than exist
between species
in the wild.
not nature do the same and
Could more,
Darwin asked, given enough time? Darwin's theory begins with the
bution blends with the mother's in the
same way blue and red paint blend to form purple. Critics ot Darwin pointed out that il this model were correct, any new trait that might evolve would be lost
obser\'ation that, in nature,
through subsequent blending, just as the
trait
and red colors are lost when
legs.
original blue
much
offspring are born there
may happen
that
many more
sur\'ive.
Since
between individuals,
it
some offspring acquire
a
variation
is
than
not present in their peers— say, longer renders the youngsters
this trait
If
they form purple.
better suited than their peers to the eco-
By contrast, in Mendel's model genes behave more like separate particles, being
logical
inherited essentially unchanged.
Mendel's work was re-discovered,
welcomed
enthusiastically
and integrated
When it
was
by Darwinists
into the theory of natural
selection. (This modification of
Darwin-
ter
niche they inhabit, they have a bet-
chance of surviving, and thereby
passing the
trait
on
to their offspring. If the
trend continues over several generations, eventually animals legs will
do
not.
come
The
trait
that
possess longer
outnumber those who has become established.
to
10
Darwin dubbed selection, to
this
emphasize
process natural its
parallels to
what breeders do when they given
traits.
select for
Unfortunately, the term
implied that nature was capable of actually
"selecting"— of foreseeing what
needed, of choosing appropriate
traits,
Of course, nature can do none
Darwins innovation was
to
declare natural selection a force to
produce new Yet
species.
natural
produce new
selection
characteristics.
does not only acts
It
is
upon
The
real
of
source of evolutionary novelty— of
new
guiding and directing the process of evolution.
species.
of
is merely between organism and environment that weeds out harmful traits and allows helpful traits to become
traits
already
traits that
exist.
and structures— must be located
m
the genetic material.
these things. Natural selection the interaction
established.
Darwin did not
originate the idea of
Several
naturalists—
natural
selection.
notably
Edward Blyth— had observed
that natural
selection takes place in
to
develop widely differing offspring,
not by adding genetic material to the gene pool, but by selecting smaller sets
of genes from the larger
and
richer
store of genetic material.
People sometimes give the impression that any change is evidence for Darwinism. But Darwinism is not just any
change.
It
is
a very special
kind— the
transformation of one type of organism into another Picture in
had described it as a purely conserving force, a mechanism for weeding out unfit individuals and
evolutionary
thereby aiding the survival of existing
branch on
nature. However, they
Dogs are bred
How Living Things Change
tree.
by breeders
is
your mind an
The change produced
horizontal change, the
flowering and elaboration of a single that tree.
What
is
needed.
11
however,
is
To put
change leading up the and creating a new branch.
vertical
evolutionary tree it
another way, breeders can
produce sweeter corn or fatter cattle, but they have not turned corn into another kind ot plant or cattle into another kind of animal. What breeders accomplish is diversification within a given type, which occurs in microevolution. What is needed is the origin ol new types, or macroevolution. Neo-Darwinism assumes that microevolution leads to macroevolution. To put that into English, it assumes that smallscale changes will gradually accumulate and produce large-scale changes. The genetic sources of change in living things are mutation and recombination.
Such stressed populations may a tendency to rebound toward the species' average morphology. Populations seem to retain an average morphology, and the same level of variability. Chromosomal recombination may exchange parts of gene sequences. But there is no evidence that such "new" genes can provide the novel traits which natural selection needs if they are to accumulate for the endless vertical change necessary for Darwinian evolution. fertility.
often
show
Mutations: Interference in the Genetic Message Recombination existing genes.
New Patterns
Old Genes
in
Most variations are produced by recom-
The tremendous differences that divide a Pekingese, a Poodle, and a Greyhound illustrate the bination of existing genes.
may
range of variation that
exist within
gene pool of a single interbreeding population. These variations are produced the
when dog breeders genes governing
size,
isolate
particular
curly hair, or speed
is
merely reshuffling of
The only known means of
introducing genuinely new genetic material into the gene pool is by mutation, a change in the DNA structure. Gene mutations occur are altered cals,
when
individual genes
from exposure
or radiation.
tions occur
chemi-
to heat,
Chromosome
aberra-
when sections of the DNA are lost, or moved to
duplicated, inverted,
another place in the
DNA molecule.
As the central mechanism of evolution, mutations have been studied inten-
within a single breed. The genes can be
sively for the past half century.
combined and recombined in a vast number of different ways. Most changes in the living world are produced in this
fly
way— not by the introduction of anything
generations. In addition, the
new
been bombarded with radiation
gene pool, but by simple recombination of existing genes. into the
Intensive breeding interesting
and useful
may produce varieties,
but
it
bility to It
disease or environmental change.
also tends to concentrate defective traits
through inbreeding, and the farther the
morphology is
from species norm produces developmental discordance, stress, and decreased (average), the
shifted
more
it
fruit
have
flies
to in-
crease the rate of mutations. Scientists
now have a pretty clear idea what kind
of
mutations can occur
tends to deplete the adaptive gene pool of the lineage, leading to increased suscepti-
The
been the subject of many experiments because its short lifespan allows scientists to observe many (see Figure 3) has
There ate
new
is
no evidence mutations creThey merely alter
structures.
existing ones. Mutations have produced, for example,
crumpled, oversized, and
undersized wings. They have produced double sets of wings. But they have not created a
new kind
they transformed the
of wing.
Nor have new
fruit fly into a
12
What search
that process?
is
underway
is
Although
re-
to test various sug-
gestions, at present there
no accepted
is
genetic theory to replace neo-Darwinism.
Evolutionists continue to be
committed
to
the belief that macroevolution occurs but are uncertain
how
it
occurs.
Intelligent Design:
remrn
Let us
an
giraffe's
but
The standard explana-
the giraffe's long neck
for
advantage
it is
integral part of the animal's
overall structure. tion
The
to the giraffe.
may appear awkward,
long neck actually
Package Deal
it
gives the animal
the
is
when com-
peting for food with shorter-necked varieties.
This advantage would have pro-
moted Figure
3.
kind of
Rapid
reproduction and abundant supply maki fruit jlics, especially
Drosophila
,
excellent subjects for
expehmcnts designed
insect.
Experiments have simply
produced variations of fruit Mutations are quite
the fact
flies.
rare.
This
is
for-
tunate, for the vast majority are harmful,
although the
some may be
neutral. Recall that
DNA is a molecular message. A muta-
tion
is
a
random change
in the
message,
to investigate
mutations.
akin to a typing error. Typing errors rarely
improve the
message;
if
too
quality of a written
many
may
occur, they
even destroy the information contained in
it.
Likewise, mutations rarely improve
the quality of the
DNA
many may even be
too
message, and lethal
to
the
organism.
Macroevolution changes observed in the laboratory
A dunking giraffe. When a giraffe
All
head to the ground to graze or drink, only an adaptational package of
represent microevolution,
bends
its
sophisticated blood pressure controls keeps the blood ves-
and the breeding pen are
limited.
They
not macro-
evolution. These limited changes
do not
way Darwinian
evolu-
accumulate the
tionary theory requires in order to
produce macro changes. The process that
produces
macroevolutionary
sels in the giraffe's
changes must be different from any that
brain from bursting.
geneticists
have studied so
far.
the long-necked variety's survival
in greater
head
numbers. That may be
IS
down
that the giraffe also to the
ground
drink water. Given the
to eat
giraffe's
true,
but
bends its grass and long
legs.
neck may just as well be required to reach the ground as the trees. And both the long neck and long legs facilitate Its
feeding in tree tops.
The
giraffe
is
an
13
adaptational package in
which each
suited to the others. Trying to explain
part
is
which
one came first is like trying to decide which came first, the chicken or the egg. The story doesn't end here. The very special circulatory
giraffe requires a
system.
When standing upright, its blood
pressure must be extremely high to force
blood up
long neck;
its
this,
in turn,
requires a very strong heart. But the giraffe lowers
head
its
when
to eat or drink,
rushes down and could produce such high pressure in the head that the blood vessels would burst. To counter this effect, the giraffe is equipped with a coordinated system of blood presthe blood
sure controls. Pressure sensors along the neck's arteries monitor the blood pres-
sure and activate contraction of the artery walls (along with other
mechanisms)
legs are
In short, the giraffe represents not a
mere collection of individual traits but a package of interrelated adaptations. It is put together according to an overall design that integrates
Where
tern.
giraffe
evolved to
it
is difficult
to
Darwinian theory, the its present form by the
explain
how a random
process could offer to natural selection an integrated package of adaptations, even
over time.
Random mutations might ade-
quately explain change in a relatively isolated
trait,
prey
to natural
such as
su^ests that the
overall, integrated
was present from
accumulation of individual, random changes preserved by natural selection. But
makes the giraffe easy enemies. The interdepen-
the powerful kick
parts into a single pat-
did such an adaptational
to
preceded by the long neck, the
weight and accessibility of the neck without
dence of the structures, therefore, strongly all
package come from?
According
Qlraffe evolution
to
counter the increase in pressure.
color.
But major
package
the beginning. Scientific
literature often reports
such interdepen-
dence of structures. In some
cases, as
with
certain brachiopods, this interdependence traces right
back to
in the fossil record
their
abrupt appearance
with the
first
evidences
body plans on earth. How likely is it that random mutations will come together and direct of diverse animal
the formation of just Let's
one new structure?
say the formation of an insect wing
changes, like the macroevolution of the
requires only five genes (an extremely
giraffe
from some other animal, would require an extensive suite of coordinated
estimate).
The complex circulatory system of the giraffe must appear at the same time as its long neck or the animal
wing information required could
adaptations.
will
not survive.
If
the various elements of
Although
insufficient, let's also
from
a single
it is
suppose that the new
mutation per gene.
sonable estimate
new mutation
is that, at
will
arise rea-
occur in only one
individual, out of a population of
long neck, they are meaningless.
that rate, the probability of two
the long
A
most, a single
the circulatory system appear before the If
low
almost certainly
1
,000. At
mutations
As viewed from the Far Side. Notiee that in Far Sides giraffe
some parts of tiie adaptational pack-
age fad to arrive on schedide!
14
If a building
is
to
be
functional, there
must be a blueprint or plan to integrate its many materials into a coordinated whole.
appearing
m the same individual
1,000,000,
The odds of
is
one
in
mutations
five
occurring are one in one thousand million million. is
no
Thus
all
biologists recognize there
chance that
realistic
tions will occur within the
five
all
life
muta-
account reduces the odds against
these mutations, but
odds against mating pair
it
also increases the
an organism
is
made
a
ecological
produce a new
will
comes
first.
new
We
new
organism, as in
house,
the
blueprint
cannot build a palace by
tinkering with a tool shed
and adding bits
marble piecemeal here and there
of
We
begin by devising a plan for the
ha\'e to
palace that coordinates
all
the parts into
an integrated whole
new
mechanism capable
of
gin of
new organisms
in material causes,
the accumulation of individual
generating not piecemeal change, but integrated, systemic change (affecting an organism's overall physical structure)
the bits of marble
added
Intelligent design,
by
seems
origin of
to be needed. Minor changes caused by recombination of genes and by
may be
acted
upon by
natural
traits.
akin to saying the origin of a palace
is
mutation
its
Dai-winian evolution locates the ori-
To explain the appearance of types,
creating a
In
disadvantage.
body
better within
plan.
building a
ol
many structures that must appear at the same time and work together in an integrated whole, if they are not to work to its
fit
body plan
current
body
their converging in a single Yet,
to
it
niche But no amount of fine-tuning of its
cycle of a
single organism. Taking large populations into
selection to tme-tune an organism, ena-
bling
cause:
m
That is
in
to the tool shed.
contrast, locates the
new organisms
in
an immaterial
a blueprint, a plan, a pattern,
devised by an intelligent agent.
15
The Origin
of Species
OVERVIEW SECTION
Hawaiian Honeycreepers are
most unusual and
anywhere
in the
among
colorful birds
the
found
world. Their plumage
reflects a beautiful
range of colors, and
the shapes of their bills vary widely too.
One
variety {Hcmignathus munroi) pos-
sesses a unique adaptation: the lower is
straight
chisel,
wood is
and heavy and
is
used
bill
like a
woodpecker-style, to bore into the to find insects,
while the upper
long and curved and
is
used as a probe
^S^m^
;l
bill
^
to
3
pry out
insects.
By
contrast.
Honey-
creepers on the North American main-
Why
land are relatively drab birds.
are
the Hawaiian Honeycreepers so different
from
their counterparts
Some
on the mainland?
of the world
s
most
colorful
species inhabit islands. Cut off from the
mainland, and exposed species develops in directions. tion that
to
new
habitats, a
new and unusual
We noted in the previous sec-
change
is
limited to variation
Hawaiian Honeycreepers. There are distinct differences
l